A Multi‐Scale Approach for Modeling the Optical Response of Molecular Materials Inside Cavities

Zerulla, Benedikt; Krstić, Marjan; Beutel, Dominik; Holzer, Christof; Wöll, Christof; Rockstuhl, Carsten; Fernandez‐Corbaton, Ivan

doi:10.1002/adma.202200350

Cited by 25 publications

(83 citation statements)

References 52 publications

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“…We define the circular dichroism as CD = A + −A − 2 , where A + and A − are the absorption of lefthanded and right-handed circularly polarized plane waves, respectively. We observe in Figure 6(c) that the results obtained with the homogeneous model match perfectly those obtained with mpGMM, which explicitly considers the discrete SUR-MOF lattice [18].…”

Section: A Bi-anisotropic and Chiral Molecular Materialssupporting

confidence: 67%

“…The band diagrams in Figure S2 show that the molecular material is homogenizable in the considered frequency range. The T-matrix of the unit cell is computed using TD-DFT [18]. The lattice constants are in x-and y-direction a 1 = a 2 = 2.079 nm, and in z-direction a 3 = 1.922 nm.…”

Section: A Bi-anisotropic and Chiral Molecular Materialsmentioning

confidence: 99%

“…We observe that the chirality is anisotropic. (c) Comparison of the absorption of an incident left-circularly polarized plane wave and the circular dichroism of a 77 nm thick slab computed with the effective material parameters, and directly with mpGMM which considers the discrete lattice explicitly[18]. The two results match perfectly.…”

mentioning

confidence: 93%

“…The T-matrix and Ewald's method can be combined in numerical codes for computing the electromagnetic response of infinitely periodic systems [12][13][14], achieving efficiencies more than two orders of magnitude better than numerical solvers of Maxwell differential equations [15,16]. The calculations of the T-matrices of molecular unit cells by quantum-mechanical ab initio methods [17], in particular time-dependent density-functional theory (TD-DFT) [18,19], enable the consideration of systems including slabs of molecular materials such as optical planar cavities filled with SURMOFs [18]. Unfortunately, Ewald's method cannot be used for finite arrangements of scatterers, such as an object of finite shape made from a 3D lattice of unit cells.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

A T-matrix Based Approach to Homogenize Artificial Materials

Zerulla¹,

Venkitakrishnan²,

Beutel³

et al. 2022

Preprint

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The accurate and efficient computation of the electromagnetic response of objects made from artificial materials is crucial for designing photonic functionalities and interpreting experiments. Advanced fabrication techniques can nowadays produce new materials as three-dimensional lattices of scattering unit cells. Computing the response of objects of arbitrary shape made from such materials is typically computationally prohibitive unless an effective homogeneous medium approximates the discrete material. In here, we introduce a homogenization method based on the effective T-matrix, T eff . Such a matrix captures the exact response of the discrete material, is determined by the T-matrix of the isolated unit cell and the material lattice vectors, and is free of spatial dispersion. The truncation of T eff to dipolar order determines the common bi-anisotropic constitutive relations. When combined with quantum-chemical and Maxwell solvers, the method allows one to compute the response of arbitrarily-shaped volumetric patchworks of structured molecular materials and metamaterials.

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Section: A Bi-anisotropic and Chiral Molecular Materialssupporting

confidence: 67%

Section: A Bi-anisotropic and Chiral Molecular Materialsmentioning

confidence: 99%

mentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A T-matrix Based Approach to Homogenize Artificial Materials

Zerulla¹,

Venkitakrishnan²,

Beutel³

et al. 2022

Preprint

Self Cite

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show abstract

“…[11] The T-matrix and Ewald's method can be combined in numerical codes for computing the electromagnetic response of infinitely periodic systems, [12][13][14] achieving efficiencies more than two orders of magnitude better than numerical solvers of Maxwell differential equations. [15,16] The calculations of the T-matrices of molecular unit cells by quantummechanical ab initio methods, [17] in particular time-dependent density-functional theory (TD-DFT), [18,19] enable the consideration of systems including slabs of molecular materials such as optical planar cavities filled with SURMOFs. [18] Unfortunately, Ewald's method cannot be used for finite arrangements of scatterers, such as an object of finite shape made from a 3D lattice of unit cells.…”

mentioning

confidence: 99%

A T‐Matrix Based Approach to Homogenize Artificial Materials

Zerulla

Venkitakrishnan

Beutel

et al. 2022

Advanced Optical Materials

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The accurate and efficient computation of the electromagnetic response of objects made from artificial materials is crucial for designing photonic functionalities and interpreting experiments. Advanced fabrication techniques can nowadays produce new materials as 3D lattices of scattering unit cells. Computing the response of objects of arbitrary shape made from such materials is typically computationally prohibitive unless an effective homogeneous medium approximates the discrete material. In here, a homogenization method based on the effective transition (T‐)matrix, is introduced. Such a matrix captures the exact response of the discrete material, is determined by the T‐matrix of the isolated unit cell and the material lattice vectors, and is free of spatial dispersion. The truncation of to dipolar order determines the common bi‐anisotropic constitutive relations. When combined with quantum‐chemical and Maxwell solvers, the method allows one to compute the response of arbitrarily‐shaped volumetric patchworks of structured molecular materials and metamaterials.

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Exploring Functional Photonic Devices made from a Chiral Metal–Organic Framework Material by a Multiscale Computational Method

Zerulla

Chun

Beutel

et al. 2023

Adv Funct Materials

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Electronic circular dichroism is an important optical phenomenon offering insights into chiral molecular materials. On the other hand, metal–organic frameworks (MOFs) are a novel group of crystalline porous thin‐film materials that provide tailor‐made chemical and physical properties by carefully selecting their building units. Combining these two aspects of contemporary material research and integrating chiral molecules into MOFs promises devices with unprecedented functionality. However, considering the nearly unlimited degrees of freedom concerning the choice of materials and the geometrical details of the possibly structured films, urgently it needs to complement advanced experimental methods with equally strong modeling techniques. Most notably, these modeling techniques must cope with the challenge that the material and devices thereof cover size scales from Ångströms to mm. In response to that need, a computational workflow is outlined that seamlessly combines quantum chemical methods to capture the properties of individual molecules with optical simulations to capture the properties of functional devices made from these molecular materials. The focus is on chiral properties and applying work to UiO‐67‐BINOL MOFs, for which experimental results are available to benchmark the results of the simulations and explore the optical properties of cavities and metasurfaces made from that chiral material.

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A Multi‐Scale Approach for Modeling the Optical Response of Molecular Materials Inside Cavities

Cited by 25 publications

References 52 publications

A T-matrix Based Approach to Homogenize Artificial Materials

A T-matrix Based Approach to Homogenize Artificial Materials

A T‐Matrix Based Approach to Homogenize Artificial Materials

Exploring Functional Photonic Devices made from a Chiral Metal–Organic Framework Material by a Multiscale Computational Method

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